A method of manufacturing a semiconductor device has forming a first conductive film over a semiconductor substrate, etching the first conductive film, forming a plurality of first conductive patterns arranged in a first direction, and forming a side surface on an outside of a conductive pattern positioned at an end among the plurality of first conductive patterns such that the side surface has a first inclination angle smaller than a second inclination angle of a side surface on an inside of the conductive pattern positioned at the end, forming a first insulation film over the plurality of first conductive patterns, and forming a second conductive pattern over the first insulation film.
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1. A method of manufacturing a non-volatile semiconductor memory comprising:
forming a first insulating film on a semiconductor substrate;
forming a first conductive film over the first insulating film;
etching the first conductive film by exposing an etchant gas to form a plurality of floating gates and dummy gates arranged in a first direction,
wherein the plurality of floating gates are between one of the dummy gates and another one of the dummy gates,
wherein a first side surface of an outside of the one of the dummy gates adjacent to an edge of the plurality of the floating gates is exposed to the etchant gas in etching of the first conductive film, and a first interior angle between a bottom surface of the one of the dummy gates and the first side surface of the one of the dummy gates is smaller than a second interior angle between the bottom surface of the one of the dummy gates and a second side surface of an inside of the one of the dummy gates, and
wherein a third interior angle between a bottom surface of one of the floating gate and a third side surface of the one of the floating gate and a forth interior angle between the bottom surface of the one of the floating gate and a forth side surface of an inside of the one of the floating gate are closer to 90 degrees than the first interior angle;
forming a second insulation film over the plurality of the floating gates;
forming a second conductive film over the second insulation film; and
forming a control gate extended in the first direction by etching the second conductive film;
forming a third insulating film over the control gate;
forming sidewall insulation films on sidewall of the plurality of floating gates and the control gate by etching the third insulating film;
after forming of the sidewall insulation films, forming a metal layer over the control gate, and
after forming the metal layer, forming a metal silicide film over the control gate by performing a thermal treatment.
2. The method according to
3. The method according to
4. The method according to
5. The method according to
6. The method according to
7. The method according to
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The present invention relates to a semiconductor device and method of manufacturing the semiconductor device, and more specifically, to a semiconductor memory having a floating gate.
An Electrically Erasable and Programmable Read Only Memory (EEPROM) having a floating gate and a control gate, a Metal Nitride Oxide Silicon (MNOS) memory which does not include the floating gate are conventionally known as a non-volatile semiconductor memory that holds stored information after power thereof is turned off. A flash memory is also well known as one of EEPROMs.
The control gate covers the floating gate and further extends beyond a peripheral area of a memory cell part.
A technique for reducing a resistance value of the control gate is known in which a metal silicide film is formed over the control gate. However, due to a steep slope on a side surface of the floating gate provided at an outermost end of the memory cell, a steep slope may be formed over a top surface of the control gate. If an insulation film remains at the steep slope part of the control gate, this results in a problem in that a part where the metal silicide film is not formed at the steep slope part. This leads to uneven resistance values of the control gates and thus results in deterioration in the semiconductor memory characteristics. Note that the insulation film remaining at the steep slope part of the control gate is, for example, the insulation film which is deposited such that the control gate is covered with the insulation film when a sidewall insulation film is formed over the sidewall of the control gate and which is removed by an etching back process. For the problem described above, a technique is known in which a sidewall insulation film is formed over both side surfaces of the floating gate, so that the steep slope of the top surface over the control gate can be alleviated. Moreover, another technique is also known in which a film thickness of each of the floating gates is adjusted, so that the steep slope of the control gate can be alleviated.
An aspect of the invention is a method of manufacturing a semiconductor device including forming a first conductive film over a semiconductor substrate, etching the first conductive film, forming a plurality of first conductive patterns arranged in a first direction, and forming a side surface on an outside of a conductive pattern positioned at an end among the plurality of first conductive patterns such that the side surface has a first inclination angle smaller than a second inclination angle of a side surface on an inside of the conductive pattern positioned at the end, forming a first insulation film over the plurality of first conductive patterns, and forming a second conductive pattern over the first insulation film.
A floating gate is formed such that an inclination angle of one side surface on a peripheral part side (hereinafter, referred to as an “outside”) of a floating gate positioned at least at an end among the plurality of floating gates formed over a memory cell area is smaller than an inclination angle of a side surface on the other side (hereinafter, referred to as an “inside”) of the floating gate positioned at the end.
When the floating gate is formed with etching, a distance between the plurality of adjacent floating gates in an arranged manner is short and thus the floating gates form a so-called dense pattern. On the other hand, no structural member is provided in proximity to an outside of an outermost floating gate among the plurality of the floating gates and thus the floating gates form a so-called sparse pattern. A side surface on the outside of the floating gate is formed such that the side surface is made gentler than a side surface on an inside of the outermost floating gate, by utilizing a difference between the sparse and dense patterns and devising conditions for etching a control gate, such as types of the etching gases.
In accordance with the method disclosed above, a slope of the control gate positioned over the gentle slope of the side surface on the outside of the outermost floating gate can be made gentle, in the control gate formed through a dielectric film over the plurality of floating gates. In consequence, it is possible to prevent a metal silicide film-unformed area from being formed over the control gate. Thus the method disclosed above is capable of effectively reducing deterioration in semiconductor memory characteristics due to the steep slope of the floating gate.
In the flash memory, as shown in
The other circuitry 13 includes, for example, control circuits, logic circuits and so on of the memory cell part 11.
As shown in
In the memory cell part 11 and the peripheral part 12, as shown in
A memory cell 20 includes the floating gate 23 formed through the tunnel insulation film 22 over the silicon substrate 10, the control gate 25 formed through the dielectric film 24 over the floating gate 23, and the pair of source/drain region 36 in the silicon substrate 10. The dummy cell 20a is provided at an end of the plurality of memory cells 20 and the dummy cell 20a has the same structure as that of the memory cell 20 other than that in which a dummy floating gate 23a is formed instead of the floating gate 23.
Moreover, in the memory cell part 11 and the peripheral part 12, a metal silicide film 26 is formed over the control gate 25 so as to reduce a resistance value of the control gate 25 and an interlayer insulation film 28 is formed such that the above disclosed members are covered with the interlayer insulation film 28.
A connection hole 28a which extends to reach the control gate 25 is formed, through the interlayer insulation film 28. A connection plug 27 is formed so as to fill the connection hole 28a with a conductive material. The control gate 25 is coupled to an interconnection 29 via the connection plug 27.
Note that, as shown in
The inclination angle is defined as an angle between a horizontal plane and the sloped side surface of the pattern. Note that the horizontal plane is 0 degree. A preferable inclination angle of the end 23b is from 40 degrees or more to 87 degrees or less if a film thickness of the floating gate 23 and a film thickness of the dummy floating gate 23a are approximately 40 nm to 130 nm and the distance between adjacent floating gates 23 is approximately 70 nm to 240 nm. For example, 55 degrees is preferable.
Hereinafter, a method of manufacturing the flash memory including the above structure will be disclosed.
Thereafter, the tunnel insulation film 22 including the silicon oxide, such as an insulation film having a film thickness of approximately 10 nm, is formed over the active region.
In
Note that, the dry etching is performed such that an inclination angle of a side surface on an outside (an end 31c) of a polycrystalline silicon pattern 31b provided beside the plurality of polycrystalline silicon patterns 31a is made smaller than an inclination angle of a side surface on an inside of the polycrystalline silicon pattern 31b. The inclination angle of the edge 31c is from 40 degrees or more to 87 degrees or less and, for example, 55 degrees is preferable. On the other hand, it is preferable that the inclination angle of the side surface on the inside of the polycrystalline silicon pattern 31b and inclination angles of both side surfaces of the polycrystalline silicon pattern 31a be an angle which is closer to 90 degrees than the inclination angle of the edge 31c.
In order to vertically form the side surface thereof by etching the polycrystalline silicon film (31) with the dry etching, the dry etching is performed, for example, under a condition in which a pressure is 10 mTorr, a flow rate of hydrogen bromide (HBr) gas is 120 sccm, and a flow rate of chlorine (Cl2) gas is 20 sccm.
In order to make the inclination angle of side surface on the outside of the polycrystalline silicon pattern 31b smaller than the inclination angle of the side surface on the inside thereof, the polycrystalline silicon film 31 is anisotropically dry etched with an etching gas, such as a gaseous mixture including HBr and oxygen (O2) and an oxygen content is from 2% or more to 25% or less or a gaseous mixture including HBr and nitrogen (N2) and a nitrogen content is from 2% or more to 25% or less. If the former gaseous mixture is used, for example, the dry etching is performed in a condition in which a pressure is 9 mTorr, a flow rate of HBr gas is 120 sccm, a flow rate of Cl2 gas is 20 sccm, a flow rate of carbon fluoride (CF4) gas is 20 sccm, and a flow rate of O2 gas is 4 sccm. On the other hand, if the latter gaseous mixture is used, for example, the dry etching is performed in a condition in which a pressure is 9 mTorr, a flow rate of HBr gas is 120 sccm, a flow rate of Cl2 gas is 20 sccm, a flow rate of CF4 gas is 20 sccm, and a flow rate of N2 gas is 6 sccm.
Thereafter the resist is applied over the silicon nitride film 33, and the resist is processed with the photolithography. As a result, a resist mask 34 extending in a direction parallel to the line I-I′ in
In
Next, ion implantation of an impurity, such as Arsenide (As), into the active region exposed on both sides of the control gate 25 is performed by using the silicon nitride film 33 and the control gate 25 as a mask, and then the ion-implanted impurity is activated by annealing. As a result, the source/drain region 36 is formed. Then a second silicon oxide film 37 is formed with the thermal oxidation.
Thereafter, an insulation film, such as a silicon nitride film 38, is formed over the entire surface of the silicon substrate 10 with the CVD or the like.
Note that, as shown in
On the other hand, as shown in
Next, a cobalt silicide film is formed by a reaction of silicon and cobalt over the top surface of the control gate 25 and over the source/drain region 36 with the thermal treatment. Then an unreacted cobalt film is removed with wet etching.
With the above process, the metal silicide film 26, such as a cobalt silicide film, is formed over the top surface of the control gate 25 and over the source/drain region 36.
Note that, as shown in
In
Next, the conductive material, such as tungsten, is deposited over the interlayer insulation film 28 such that the connection hole 28a is filled. Then the tungsten is polished until a surface of the interlayer insulation film 28 is exposed, with the CMP. As a result thereof, the connection plug 27 is formed.
Thereafter, the conductive material, such as aluminum or an aluminum alloy, is deposited over the interlayer insulation film 28 including the connection plug 27, the aluminum or the aluminum alloy is processed with the photolithography and the dry etching, and the interconnection 29 electrically coupled to the control gate 25 through the connection plug 27 is formed. Then the interlayer insulation film 28 is further formed over the interconnection 29.
As disclosed above, according to the embodiment, miscellaneous problems caused by the steep slope of the dummy floating gate 23a are solved and the deterioration in semiconductor memory characteristics can be effectively reduced, so that the flash memory with high reliability can be achieved.
Morioka, Hiroshi, Anezaki, Toru, Ariyoshi, Junichi
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